Recent advancements in integrated circuits demand the development of novel thermal management schemes that can dissipate ultra-high heat fluxes with high heat transfer coefficients. Previous study demonstrated the potential of thin film evaporation on microanostructured surfaces [1-11]. Theoretical calculations indicate that heat transfer coefficients on the order of 10~6 W/m~2K and heat fluxes of 105 W/cm2 can be achievable with water [1, 5-6]. However, in previous experimental setup, the coolant has to propagate across the surface which limits the increase in heat flux and the heat transfer coefficient, while adding complexity to the system design. This work aims to decouple the propagation of the coolant from the evaporation process through a novel experimental configuration. Thin nanoporous membranes of 13 mm diameter were used where a metal layer was deposited on the top surface to serve as a resistance heater. Liquid was supplied from the bottom of the membrane, driven through the nanopores by capillary force, and evaporated from the top surface. Heat transfer coefficient over 10~4 W/m~2K was obtained with isopropyl alcohol (IPA) as the coolant, which Is only two orders of magnitude smaller than the theoretical limit. This work offers insights into optimal experimental designs towards achieving kinetic limits of heat transfer for thin film evaporation based thermal management solutions.
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机译:集成电路的最新进展要求开发新颖的热管理方案,该方案可以消散具有高传热系数的超高热通量。先前的研究证明了在微/纳米结构表面上薄膜蒸发的潜力[1-11]。理论计算表明,用水可以达到10〜6 W / m〜2K的热传递系数和105 W / cm2的热通量[1,5-6]。然而,在先前的实验装置中,冷却剂必须在整个表面上传播,这限制了热通量和传热系数的增加,同时增加了系统设计的复杂性。这项工作旨在通过一种新颖的实验配置,使冷却剂的传播与蒸发过程脱钩。使用直径为13 mm的纳米多孔薄膜,其中在其上表面沉积了一层金属,以用作电阻加热器。从膜的底部供应液体,在毛细管力的作用下驱动液体通过纳米孔,并从顶表面蒸发。以异丙醇(IPA)为冷却剂,传热系数超过10〜4 W / m〜2K,仅比理论极限小两个数量级。这项工作为实现基于薄膜蒸发的热管理解决方案实现传热动力学极限的最佳实验设计提供了见识。
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